Abstract
A structural health monitoring method based on the concept of static aeroelasticity is presented in this paper. This paper focuses on the estimation of these aeroelastic effects on older transport aircraft, in particular the structural components that are most affected, in severe atmospheric turbulence. Because the structural flexibility properties are mostly unknown to aircraft operators, only the trend, not the magnitude, of these effects is estimated. For this purpose, one useful concept in static aeroelastic effects for conventional aircraft structures is that under aeroelastic deformation the aerodynamic center should move aft. This concept is applied in the present paper by using the fuzzy-logic aerodynamic models. A twin-jet transport aircraft in severe atmospheric turbulence involving plunging motion is examined. It is found that the pitching moment derivatives in cruise with moderate to severe turbulence in transonic flight indicate some degree of abnormality in the stabilizer (i.e., the horizontal tail). Therefore, the horizontal tail is the most severely affected structural component of the aircraft probably caused by vibration under the dynamic loads induced by turbulence.
Highlights
The transport aircraft experiences frequently high loads, especially in severe turbulence encounters, sudden evasive motion in avoiding air collision, and hard landings
This paper focuses on the estimation of these aeroelastic effects on older transport aircraft, in particular the structural components that are most affected, in severe atmospheric turbulence
It should be noted that the turbulent vertical wind field was not measured or estimated in the flight data recorder (FDR) but is included in the total α
Summary
The transport aircraft experiences frequently high loads, especially in severe turbulence encounters, sudden evasive motion in avoiding air collision, and hard landings. These high loads may cause structural damage, fatigue cracking, or nontypical structural deformation. These structural problems are most noticeable for aging transport aircraft. Structural integrity of an aging aircraft is determined by the level of fatigue, corrosion, and corrosion-assisted fatigue [1]. There are no perfect and sure ways to detect or predict the structural integrity of aging aircraft
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